Multi-layer impact resistant bumper

ABSTRACT

An impact resistant bumper device that is elongated along a longitudinal axis and mountable on a mounting member, the device having a cross-section having an open undersurface configuration comprising: a first layer of a first polymer material; a second layer of a second polymer material; a third layer of a third polymer material; wherein the first polymer material has been melted at least once prior to the extrusion cycle, the second polymer material is first melted during the extrusion cycle and the third polymer material is first melted during the extrusion cycle.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 13/414,885, filed Mar. 8, 2012, which is a continuation of U.S. patent application Ser. No. 12/236,107, filed Sep. 23, 2008, now U.S. Pat. No. 8,153,242, which is a continuation of U.S. patent application Ser. No. 10/954,432, filed Sep. 30, 2004, now abandoned, which claims the benefit of priority under 35 U.S.C. Sections 119 and/or 120 to the extent applicable to U.S. Provisional patent application Ser. No. 60/508,102 filed Oct. 2, 2003 for Multi-Layer Impact Resistant Bumper.

FIELD OF THE INVENTION

The present invention relates to multilayered products comprised of polymeric material and methods for producing such products. More particularly the invention relates to extruded or molded polymeric material products comprising layers that are bonded to each other, each layer comprising a polymeric material having a different selected durometer, hardness, bendability, impact resistance and/or melting point and/or concentration of dye and/or plasticizer materials.

BACKGROUND OF THE INVENTION

Extruded or injection molded products comprising two or more layers of polymer material are typically produced using complex molding or extrusion equipment and/or requiring complex processing steps that are difficult to reproduce from one extrusion or molding cycle to the next cycle. Processing methods for producing products comprised of polymer materials are typically developed by trial and error experimentation with a variety of different polymer materials having specific properties and molecular weights which, once determined are specific to production of the desired product and cannot be varied without substantially changing the end product.

SUMMARY OF THE INVENTION

The present invention relates to structural products that comprise a body of two or more polymer materials adhered or bonded to each other each polymer material having a different durometer, hardness, bendability, molecular weight or melting point or concentration of dye materials and/or plasticizers. The structural products of the invention are preferably formed as a multi-layered strip of polymer materials which is/are resistant to impact by solid objects and/or shock absorbent and resistant to shrinkage along the longitudinal or axial direction/length of the strip-form product.

In accordance with the invention there is provided an elongated strip of polymer material having a cross-section comprising:

a first inner core layer of a first polymer material having a selected configuration along the cross-section of the strip;

a second outer layer of a second polymer material bonded to an outer surface of the first inner core layer having a second selected configuration along the cross-section;

wherein the first polymer material has a softness, hardness or durometer selected to be manually bendable and compressible; and,

wherein the second polymer material has a durometer or hardness greater than the durometer or hardness of the first polymer material.

The first and second layers are preferably co-extruded simultaneously through a die and bonded during their simultaneous co-extrusion. The second polymer material comprises a meltable polymer material that is melted for the first time after its initial manufacture during the co-extrusion. The first polymer material comprises a meltable polymer material that has been melted at least one once prior to the co-extrusion. The second polymer material typically contains at least one selected dye. The first polymer material typically contains at least two selected dyes.

The elongated strip may further comprise a third layer of a polymeric material bonded to an inner surface of the first layer. In such an embodiment, the first, second and third layers are co-extruded simultaneously through a die and bonded during their simultaneous co-extrusion. The third layer typically comprises a polymeric material that is first melted during the co-extrusion.

Further in accordance with the invention there is provided, an elongated strip of polymer material extruded in an extrusion cycle having a cross-section comprising:

a first inner core layer of a first polymer material having a selected configuration along the cross-section of the strip;

a second outer layer of a second polymer material bonded to an outer surface of the first inner core layer having a second selected configuration along the cross-section;

wherein the second polymer material is first melted during the extrusion cycle; and

wherein the first polymer material has been melted at least once prior to the extrusion cycle.

In another aspect of the invention there is provided, a method of producing a structural body of two or more layers of polymeric material, the method comprising:

selecting a first polymer material that has been melted and cooled to solid form;

selecting a second polymer material that has not been melted;

extruding the first and second polymer materials simultaneously in molten form through a selected mold or die in first and second strips;

layering the simultaneously extruded first and second strips into contact with each other in their molten form upon exiting the selected mold or die in a configuration wherein the first strip as formed has an outer surface and the second strip is deposited on the outer surface of the first strip.

The step of selecting the first polymer material includes selecting a polymer material that contains a dye material and has been melted prior to the step of extruding and most preferably comprises selecting a mixture of two or more polymer materials that have been melted and cooled to solid form.

The step of extruding typically comprises forming the first polymeric material upon exiting the mold or die into a strip form having an outer visible surface and an undersurface wherein, the step of layering comprises layering the second extruded polymer onto the outer visible surface of the second polymer material.

The step of selecting the second polymer material typically comprises selecting a predetermined first polymer material having a first durometer, hardness, bendability or molecular weight wherein the predetermined polymer material converts upon melting and cooling to a converted state having a second durometer, hardness, bendablity or molecular weight that is less than the first durometer, hardness, bendability or molecular weight; and wherein the step of selecting the first polymer material comprises selecting the predetermined polymer material in the converted state.

The step of selecting the second polymer material may comprise selecting a predetermined second polymer material and the step of selecting the first polymer material may comprise selecting a mixture of two or more polymer materials each being comprised of the predetermined second polymer material and each containing a dye. In another aspect of the invention there is provided, a method of producing a structural body of two or more layers of polymeric material, the method comprising: selecting a first polymer material that has been melted and cooled to solid form;

selecting a second polymer material that has not been melted;

extruding the first and second polymer materials simultaneously in molten form through a selected mold or die into first, second and third strips;

layering the simultaneously extruded first, second and third strips into contact with each other in their molten form upon exiting the selected mold or die;

wherein the first strip is comprised of the first polymer material and the second and third strips are comprised of the second polymer material; and;

wherein the first strip is sandwiched between the second strip and the third strip.

In such an embodiment, the step of selecting the second polymer material may comprise selecting a predetermined polymer material having a first durometer, hardness, bendability or molecular weight wherein the predetermined polymer material converts upon melting and cooling to a converted state having a second durometer, hardness, bendablity or molecular weight that is less than the first durometer, hardness, bendability or molecular weight; and wherein the step of selecting the first polymer material may comprise selecting the predetermined polymer material in the converted state.

The step of selecting the second polymer material may comprise selecting a predetermined second polymer material wherein the step of selecting the first polymer material may comprise selecting a mixture of two or more polymer materials each being comprised of the predetermined second polymer material and each containing a dye.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an underside/perspective cross sectional view of a composite material extruded bumper product according to the invention showing a solid strip form extruded body of material comprising a top outer layer of relatively hard polymer material, an inner or intermediate layer of relatively soft or less hard and more bendable polymer material and an undersurface strip of relatively hard, shrink resistant polymer material;

FIG. 2 is a topside/perspective cross sectional view of the Fig. product showing the product mounted or snap fit onto a railing;

FIG. 3 is a schematic cross sectional view of the FIG. 1 product;

FIG. 4 is a rear elevational view of the first plate as seen along line 4-4 of FIG. 3;

FIG. 5 is a rear elevational view of the second plate as seen along line 5-5 of FIG. 3;

FIG. 6 is a rear elevational view of the third plate as seen along line 6-6 of FIG. 3;

FIG. 7 is a rear elevational view of the fourth plate as seen along line 7-7 of FIG. 3;

FIG. 8 is a front elevational view of the fourth plate as seen along line 8-8 of FIG. 3;

FIG. 9 is a front cross-sectional view of the FIG. 1 product; and,

FIG. 10 is an exploded perspective view of the third and fourth plates shown in FIG. 3.

DETAILED DESCRIPTION

FIGS. 1, 2 and 9 show an extruded length of a multi-strip formed bumper product 8 comprising an outer facing strip 10 of relatively hard polymer material, and intermediate strip 20 of relatively soft, rubbery or bendable polymer material and an undersurface strip 40 of relatively hard, rigid, shrink resistant polymer material. The outer coat or strip component/layer 10 is bonded during the extrusion process, preferably immediately upon exit from the final extrusion die, to the outer surface of the inner soft or manually bendable layer or strip 20 such that the end product assumes the outward visual appearance of a relatively hard, shiny surface as opposed to the inner layer 20 which cannot be visually seen when mounted on a rail 30 as shown in FIG. 2.

FIG. 2 shows the elongated strip-like product 8 mounted on a rigid, inflexible metal rail 30 by snap fitting of preformed tongues or detents 55 formed on the underside 57, FIG. 1, of the core 20 strip/layer onto a complementary receiving set of grooves or detents 59 formed on the outside surface the rail 30 shown in FIG. 2.

As shown in FIG. 3, the composite material feed for the core 20 is fed directly from the exit barrel 6 of the extruder through a central composite material bore 50 that extends through each of plates 1-4. The polymer feed for the cap coat 10 is fed through an aperture 60 extending from the exit side to the entrance side of plate 4 through plate 4, the feed then being routed through a bore 70, FIGS. 7, 8, 10 on the entrance side of plate 4 such that the cap coat material feed is ultimately routed through plate 4 and out the exit side of bore 70 on the exit side of plate 4, FIGS. 7, 8, 10 simultaneously with the extrusion of the feed material for the core 20 being routed through central bore 50. The polymer feed for the rigid non-shrink strip 40 is initially fed through an aperture 80 extending from the exit side to the entrance side of plate 4 through plate 4, the feed then being routed through a groove 90, FIGS. 7, 8, on the entrance side of plate 4 such that the rigid strip 40 material is ultimately routed through plate 4 and out the exit side of bore 100 on the exit side of plate 4 simultaneously with the extrusion of the feed material for the core 20 being routed through central bore 50 and the feed material for the cap coat 10 being routed through bore 70. Thus all three separate streams of polymer materials comprising the cap coat 10, core 20 and rigid undersurface strip 40 are simultaneously co-extruded and come into contact with each other in a molten state immediately upon exit from the exit side of plate 4. Once the three co-extruded streams of materials come into contact with each other in the molten state, the materials firmly bond to each other during and upon cooling to form the product shown in FIGS. 1, 2, 9.

FIG. 3 shows an additional end plate 5 that may be used together with the plates 1-4 assembly, the exact configuration and use of plates and equipment to effect the fluid material feed connections to the bores of plates 1-4 being a matter of design choice for the skilled artisan. The disclosed embodiment showing the use of four separate plates 1-4 is shown for purposes of example only. Any number or configuration of extrusion plates that achieve the function of routing of the thermoplastic polymer materials as shown may be used in the process. Positioning the exit ends of feed bores 50, 70, 80 in close adjacency to each other such that the separate streams of exiting polymer materials contact the surfaces of each other upon exit from the extrusion plates is most preferred so that the separate streams of exiting polymer materials come into contact with each other in a molten state immediately upon exit and thereby adhere to each other upon cooling from the molten state to a stable cooled state. When the separate streams of polymer materials come into contact with each other in the molten state the mating surfaces mix together somewhat at the point of contact and upon cooling to a crystalline state become essentially adhered to each other to form a the unitary product 8 shown in FIGS. 1, 2, 9. The separate streams of extruded polymer materials may alternatively be bonded to each other with a bonding material.

FIGS. 3, 10 show a solid rod or wire 200 that may be positioned through the end portion of bore 50 in the middle of the detent 55 configuration of the core 20 strip to enable an elongated aperture 25 to be formed within the body of the detent during the extrusion process to impart additional bendability or flexibility to the detent 55. Such additional flexibility imparted to the detent 55 better enables the detent to be manually snap fit around or over the outer surface of the complementary protrusion or detent 59 of the rail 30 onto which the bumper strip 8 is mounted. The snap fitted mounting of detents 55 onto the protrusions 59 firmly holds the bumper 8 on the rail 30.

The core material 20 typically comprises a mixture of polymer materials that have been previously processed and melted in a prior extrusion or injection molding cycle, e.g. a mixture of scrap materials from previous extrusion cycle runs of one or more selected thermoplastic polymer materials such as polyvinyl chloride (PVC) where each scrap material contains a different concentration/amount of dye material and/or a different durometer or hardness. The subsequent extrusion processing cycle carried out on previously extruded or molded materials causes the composite material now being melted a second time in the course of an extrusion or molding process to assume a lower durometer than the originally extruded product comprising virgin material and/or a greater rubberiness, flexibility or bendability than the original virgin material. The lower durometer of scrap material may also be a result of the scrap materials containing several different dye and other additives such as plasticizers and the like.

As used herein the phrase “melted for the first time” or “first melted” or the like means that the polymer material has not been previously melted during an extrusion or molding process, it being understood that the starting polymer material may have been previously in a molten form as a result of its having been produced/manufactured in the first instance.

The cap coat 10 thermoplastic material selected is preferably virgin polymer material that has not been previously extruded or otherwise melted and typically does not initially contain a dye. The cap coat 10 material upon extrusion has a higher durometer, rigidity and less rubberiness, flexibility and bendability than the core material 20. One or more dye materials that comprise between about 3% and about 10%, e.g. 4-7%, by weight of the cap coat polymer material may be mixed with/added to the thermoplastic starting feed material for the cap coat 10.

The non-shrink strip material 40 is also preferably comprised of a virgin polymer material that has not been previously extruded or otherwise melted. Most preferably, the non-shrink strip material is the most rigid of the three polymer materials and is the most resistant to shrinkage particularly in/along the longitudinal direction of the elongated strip-form product 8. The non-shrink material may comprise the same or substantially the same virgin polymer material as the core 20 material. The rigid strip 40 provides a particular resistance to shrinkage of the core material 20 along the longitudinal or axial length of the elongated extruded strip-like product 8 by virtue of being bonded to the underside of the core 20 strip. Such resistance to shrinkage by virtue of the bonding of the non-shrink strip 40 to the core strip component 20 thus obviates the necessity for replacing edge, end or corner pieces that are typically attached to or mounted at the ends of a finished strip product 8 once installed on a rail 30 in an actual shelf, counter or other retail store environment.

The polymer material selected for use in comprising the cap coat 10 and the core 20 typically comprises the similar basic polymers, mixture of polymers or thermoplastic materials, e.g. thermoplastic polyvinyl chlorides, nylons, polyesters, polyethers, polyamides, rubbers and latex rubber materials and copolymers of one or more of all of the foregoing. That is the polymer materials of which the cap coat 10 and the core 20 are comprised typically have essentially the same units making up the polymer backbone. The polymer material of the cap coat 10 and core 20 materials typically differ somewhat in polymer chain length, degree of cross polymerization (if any) or in concentration and composition of dye materials contained within the matrix of the materials. For example, the virgin cap coat 10 material typically comprises a polymer material having a durometer of between about 75 and 90, e.g. 80-85, and the core layer 20 material comprises a mixture of two or more scrap materials that were originally extruded from the same basic material as the cap coat 10 material containing the same or different dye materials at the same or different concentrations as the cap coat 10 material contains.

Polymer materials suitable for use in the invention are thermoplastic polymers that are relatively pliable or manually bendable such as polyvinyl chloride, polyamide, polyether, polyester and copolymers of all of the foregoing with one or more of each other or with urethane or other polymer units that impart a suitable manual bendability to the end polymer. Stiffeners, plasticizers, catalysts and the like may be contained within the polymer materials to impart any desired degree of flexural modulus, hardness, impact resistance and like mechanical/physical properties to the polymer material. 

What is claimed is:
 1. An impact resistant bumper device that is elongated along a longitudinal axis and mountable on a mounting member, the device having a cross-section having an open undersurface configuration comprising: a first layer of a first polymer material consisting essentially of a recycled mixture of polymer materials; a second layer of a second polymer material, said second polymer material consisting essentially of virgin polymer material; wherein the first layer is formed into an inner core body having an outer surface and an open undersurface; wherein the second layer is formed into a layer bonded to the outer surface of the first layer; and a third layer of a third polymer material formed into an elongated strip bonded to the undersurface of the first layer , said third polymer material consisting essentially of virgin polymer material.
 2. The impact resistant bumper device of claim 1 wherein the first and second layers are co-extruded simultaneously through a die and bonded during the extrusion cycle.
 3. The impact resistant bumper device of claim 1 wherein the first polymer material has a durometer selected to be manually bendable and compressible; and, wherein the second polymer material has a durometer greater than the hardness or durometer of the first polymer material.
 4. The impact resistant bumper device of claim 3 wherein the third polymer material has a durometer greater than the durometer of the first polymer material and greater than the durometer of the second polymer material.
 5. The impact resistant bumper device of claim 1 wherein the first, second and third polymer materials each separately comprise a polyvinyl chloride.
 6. The impact resistant bumper device of claim 5 wherein the first, second and third polymer materials each separately consist essentially of a polyvinyl chloride.
 7. An impact resistant bumper device that is elongated along a longitudinal axis and mountable on a mounting member, the device having a cross-section having an open undersurface configuration comprising: a first layer of a polymeric material consisting essentially of recycled polyvinyl chloride; a second layer of a polymeric material consisting essentially of virgin polyvinyl chloride; wherein the first layer is formed into an inner core body having an outer surface and an open undersurface; wherein the second layer is formed into a layer bonded to the outer surface of the first layer; and a third layer of a polymeric material consisting essentially of virgin polyvinyl chloride that may be the same as or different from the virgin polyvinyl chloride of the second layer, said third layer formed into an elongated strip bonded to the undersurface of the first layer.
 8. The impact resistant bumper device of claim 7 wherein the polymeric material of the first layer has a durometer selected to be manually bendable and compressible; and, wherein the polymeric material of the second layer has a durometer greater than the durometer of the polymeric material of the first layer.
 9. The impact resistant bumper device of claim 7 wherein the polymeric material of the third layer has a durometer greater than the durometer of the polymeric material of the first layer. 